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Regret Equals Covariance: A Closed-Form Characterization for Stochastic Optimization

2 Pith papers cite this work. Polarity classification is still indexing.

2 Pith papers citing it
abstract

Regret is the cost of uncertainty in algorithmic decision-making. Quantifying regret typically requires computationally expensive simulation via Sample Average Approximation (SAA), with complexity $\mathcal{O}(Bn^{2}d^{3})$ in the number of scenarios $B$, variables $n$, and constraints $d$. % This paper proves that expected regret in any stochastic optimization problem admits the exact decomposition % \begin{equation*} \mathrm{Regret}(c) = \mathrm{Cov}(c,\,\pi^{*}(c)) + R(c), \end{equation*} % where $c$ is the vector of uncertain parameters, $\pi^{*}(c)$ is the optimal decision, and $R(c)$ is a residual whose magnitude we bound explicitly under Lipschitz, smooth, and strongly convex conditions. % For linear programs and unconstrained quadratic programs, including the classical Markowitz portfolio problem, we prove $R(c)=0$ exactly, so that $\mathrm{Regret}(c) = \mathrm{Cov}(c,\pi^{*}(c))$ holds without approximation. % When historical cost-decision pairs $\{(c_i, \pi^*(c_i))\}$ are available, the covariance can be estimated in $\mathcal{O}(nd^{2})$ time, which is orders of magnitude faster than SAA. The estimation is performed by a single pass through the data. % We derive concentration bounds, a central limit theorem, and an asymptotically unbiased residual estimator, and we validate all results on synthetic LP, QP, and integer programming instances and on a rolling-window portfolio experiment using ten years of CRSP equity data.

fields

econ.EM 2

years

2026 2

verdicts

UNVERDICTED 2

representative citing papers

Liquidity-Based Audit of Algorithmic Trading Strategies

econ.EM · 2026-06-27 · unverdicted · novelty 5.0

A multi-period regret decomposition produces an observable statistic whose sign classifies linear algo strategies as liquidity consumers or providers and equals strategy size times squared Roll spread under AR(1) costs, implying N-squared welfare loss from liquidity imbalance.

Evaluating AI Investment Strategies

econ.EM · 2026-06-07 · unverdicted · novelty 4.0

Derives an exact decomposition of cumulative regret into per-period covariances for dynamic policies under i.i.d. costs and unbiased Markov policies, with extensions to non-stationary cases and RL connections.

citing papers explorer

Showing 2 of 2 citing papers.

  • Liquidity-Based Audit of Algorithmic Trading Strategies econ.EM · 2026-06-27 · unverdicted · none · ref 1 · internal anchor

    A multi-period regret decomposition produces an observable statistic whose sign classifies linear algo strategies as liquidity consumers or providers and equals strategy size times squared Roll spread under AR(1) costs, implying N-squared welfare loss from liquidity imbalance.

  • Evaluating AI Investment Strategies econ.EM · 2026-06-07 · unverdicted · none · ref 1 · internal anchor

    Derives an exact decomposition of cumulative regret into per-period covariances for dynamic policies under i.i.d. costs and unbiased Markov policies, with extensions to non-stationary cases and RL connections.